Abstract
A significant number of CSCL (Computer-Supported Collaborative Learning) environments support the learning of groups of students enabling their collaboration in solving problems. These collaborative environments usually need additional computational support to allow the automatic processing of both the actions carried out by the students and the end solution with the aim of studying the learning process and the validity of the solution proposed to the problem. This process, known as Collaboration and Interaction Analysis, is typically carried out in three phases: observation, abstraction and intervention. In this paper, we propose a methodological approach for the design of mechanisms for the observation phase. This approach provides a set of procedures enabling developers to design observation systems in CSCL environments that capture and model all the information required for comprehensive analyses of the collaboration process and the resulting solution to the problem. This methodological approach is put into practice by means of its use in the design of an observation system in the SPACE-DESIGN (SPecification and Automatic Construction of collaborative Environments of DESIGN) collaborative environment.
Highlights
CSCL (Computer-Supported Collaborative Learning) environments provide shared workspaces where students carry out learning activities using tools for learning object manipulation, discussion and coordination
There is a clear need for a computer-supported analysis process to characterize the type of collaboration undertaken by the students and its influence in the learning process [8] as well as the benefits provided by collaboration in the learning process [15]
This paper presents a methodological approach that fills the aforementioned gap with a set of procedures and techniques for the design of observation mechanisms to process all kinds of significant information coming from the use of a CSCL environment following a problem-solving approach to learning
Summary
CSCL (Computer-Supported Collaborative Learning) environments provide shared workspaces where students carry out learning activities using tools for learning object manipulation, discussion and coordination. This paper presents a methodological approach that fills the aforementioned gap with a set of procedures and techniques for the design of observation mechanisms to process (capture, represent and store) all kinds of significant information coming from the use of a CSCL environment following a problem-solving approach to learning. This is oriented to software developers, so that they have a technological support to facilitate their work of building interaction automatic observation systems.
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